KR102495144B1 - Sound-absorbing panel capable of absorbing broadband and method for manufacturing a sound-absorbing panel - Google Patents

Abstract

The present invention relates to a sound absorption panel, which comprises: a step of generating a first mixing material in which recycled polyester and low melting (LM) polyester are mixed at the weight ratio of 20-60% : 80-40%; a step of generating a second mixing material in which recycled polyester and LM polyester are mixed at the weight ratio of 80-40% : 20-60%; a step of mixing and heating the first mixing material and the second mixing material; and a step of fabricating a sound absorption panel by forming a front surface portion at a predetermined thickness and shape by performing compression molding. The front surface portion has a surface area and at least one curved area of which one portion is formed in a groove shape at the surface area. The curved area may comprise: a first curve which is the boundary of the upper portion; a second curve which is the boundary of the lower portion; and a groove area provided between the first curve and the second curve. Therefore, the present invention can be conveniently installed.

Description

Sound-absorbing panel capable of absorbing broadband and method for manufacturing a sound-absorbing panel

The present invention relates to a sound absorbing panel that absorbs low and medium frequency bands and a method for manufacturing the sound absorbing panel, and more specifically, to reduce noise, appropriately adjust reverberation, and to a wide range of not only high and medium frequency bands but also low frequency bands. It relates to a sound absorbing panel capable of enhancing sound absorbing performance.

Polyester is a type of polymer that is durable but not hygroscopic. Such polyester is weak against heat, does not wrinkle well, and does not change its shape well. Accordingly, polyester is used in various fields.

That is, polyester is widely used as a fiber for clothing and furniture covers, blankets, computer mouse pads, waterproof sheets, industrial ropes, belts, and the like. In addition, it is also used for a sound absorbing material for reducing noise in a space. Sound absorbing materials are installed on ceilings or walls to reduce unwanted noise as well as to reduce reverberation.

Conventional sound absorbing materials made of polyester only reduce noise in a high frequency band, but have a problem in that they do not effectively reduce noise in a mid-to-low frequency band.

In addition, when installing the sound-absorbing material, construction materials were required, and on-site processing was essential. Accordingly, it is not easy to install the sound absorbing material such as a ceiling or a wall.

Therefore, a method for manufacturing a modular sound-absorbing panel and easily installing the sound-absorbing panel in various spaces is being sought, and at this time, a method for reducing noise in a broadband including not only the mid- and low-frequency band but also the low frequency band is being sought.

Korean Patent Registration No. 10-2185081

The present invention is to solve the problems of the prior art as described above, by manufacturing a sound absorbing panel to easily absorb sound even in a low frequency band by improving the limit that a sound absorbing panel made of polyester can easily absorb sound only in a mid- and high-frequency band, Its purpose is to reduce noise and reverberation over a wide range.

In addition, an object of the present invention is to be a modular sound-absorbing panel, which requires no on-site processing and can be easily installed.

In addition, an object of the present invention is to easily install sound-absorbing panels in spaces of various uses and scales.

In addition, an object of the present invention is to manufacture a sound absorbing panel to be easily changed in color during the manufacturing process.

A method for manufacturing a sound absorbing panel according to the present invention for achieving the above object is to create a first mixed material in which Recycle polyester and LM polyester (Low Melting Polyester) are mixed in a weight ratio of 20 to 60%: 80 to 40% ; Creating a second mixed material by mixing recycled polyester and LM polyester at a weight ratio of 80 to 40%: 20 to 60%; mixing and heating the first mixed material and the second mixed material; And performing compression molding to form a front portion with a predetermined thickness and shape to manufacture a sound absorbing panel, wherein the front portion has a surface area and at least one curved area, a portion of which is formed in a groove shape, in the surface area. , The curved region may include a first curve that is a boundary of an upper portion, a second curve that is a boundary of a lower portion, and a groove region between the first curve and the second curve.

Here, the front part may be formed to have a maximum width of 600 mm and a maximum length of 600 mm.

In addition, a side portion bent from each side of the front portion is formed, and the length of the side portion may be formed to be 50 mm to 60 mm.

In addition, the surface region and the side portion are made of compressed polyester, and the compressed polyester may serve as a plate vibration type sound absorbing material.

In addition, when the surface area and the side part are installed on the wall, the wall and the rear air layer can be formed to absorb noise in a low frequency band.

In addition, the step of mixing and heating the first mixed material and the second mixed material may be heated in an oven at 300° C. to 350° C., and the heating time may be 70 seconds to 200 seconds.

In addition, the step of manufacturing a sound absorbing panel by performing the compression molding to form a front portion with a predetermined thickness and shape is pressurized using a press, but the pressing time may be 50 seconds to 200 seconds.

In addition, the manufactured sound-absorbing panel may have a weight of 1,500 g/m ³ to 2,000 g/m ³ of polyester.

On the other hand, the sound absorbing panel according to the present invention for achieving the above object is formed in a polygonal shape and includes a front portion having a predetermined size and thickness, and the front portion has a surface area and at least a portion of the surface area is formed in a groove shape. One bending region may be formed, and the bending region may include a first curve that is a boundary of an upper portion, a second curve that is a boundary of a lower portion, and a groove region between the first curve and the second curve.

Here, the groove area may be formed in the form of a concave groove having a shallow depth near the first curve and the second curve and a deeper depth as it moves away from the first curve and the second curve.

In addition, the bending area is formed by connecting from one side of the front portion to the other facing side, the first curve and the second curve are formed in the shape of a wave, and the first curve formed in the shape of the wave And the second curves may be formed symmetrically with each other.

In addition, the concave groove shape may be formed to a thickness of 4 mm to 10 mm.

In addition, the groove area may be formed to be thicker in a central portion than near the first curve and the second curve.

In addition, a side portion bent from each side of the front portion is formed, and the side portion may be formed inclined outward from the front portion when viewed in a cross-sectional view.

The sound-absorbing panel and the method for manufacturing the sound-absorbing panel according to the present invention have the following effects.

First, it has excellent sound absorption performance with a broadband. The sound absorbing panel according to the present invention has excellent sound absorbing performance in a low frequency band due to the sound absorbing performance of the middle frequency band of the polyester and the plate vibrating type sound absorbing material compressed with polyester and the air layer behind it. Therefore, since it effectively reduces noise in the mid- and low-frequency band as well as in the low-frequency band, it has excellent sound absorption performance in a wide band.

Second, by installing in various spaces, noise and reverberation can be reduced. The sound absorbing panel according to the present invention is a modular sound absorbing panel, and DIY (Do It Yourself) installation is possible without the need for subsidiary materials, and the user can properly select the number of sound absorbing panels and install them simply. Accordingly, by properly selecting and assembling the number of sound-absorbing panels in spaces having different volumes, such as buildings, ships, vehicles, and railways, it can be customized and installed in spaces having different volumes. Therefore, while the user easily installs the sound-absorbing panel in different spaces such as buildings, ships, vehicles, and railways, noise generated in the space can be effectively reduced.

Third, it can be manufactured in various colors. The sound absorbing panel according to the present invention may be manufactured by additionally adding a layer to the front surface in the manufacturing step. At this time, the added layer may be a layer of a different color or pattern (pattern) from the sound absorbing panel initially manufactured. Therefore, since the color of the sound absorbing panel can be changed by simply adding an additional layer to the front of the existing sound absorbing panel in the manufacturing step, it is easily manufactured in various colors, and accordingly, by installing the user using a sound absorbing panel of various colors, Various visual effects can be produced in the interior space. In addition, the sound absorption performance may be further enhanced by adding additional layers.

1 is a perspective view of a sound absorbing panel according to an embodiment of the present invention.
2 is a plan view of a sound absorbing panel according to an embodiment of the present invention.
3 is a side view of a sound absorbing panel according to an embodiment of the present invention.
4 is a side cross-sectional view of a sound absorbing panel according to an embodiment of the present invention.
5 is a bottom view of a sound absorbing panel according to an embodiment of the present invention.
6 is a view schematically illustrating reducing noise in a middle and high frequency band through a curved region in a sound absorbing panel according to an embodiment of the present invention.
7 is a diagram schematically illustrating reducing noise of a low frequency band in a sound absorbing panel according to an embodiment of the present invention.
8 is a view schematically showing that a layer is additionally attached to the front part in a side view of a sound absorbing panel according to an embodiment of the present invention.
9 is a view schematically illustrating the assembly and installation of a plurality of sound absorbing panels according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, some configurations irrelevant to the gist of the present invention will be omitted or compressed, but the omitted configurations are not necessarily unnecessary in the present invention, and can be combined and used by those skilled in the art to which the present invention belongs. can

1 is a perspective view of a sound absorbing panel according to an embodiment of the present invention, Figure 2 is a plan view of a sound absorbing panel according to an embodiment of the present invention, Figure 3 is a side view of a sound absorbing panel according to an embodiment of the present invention, Figure 4 is a side cross-sectional view of a sound absorbing panel according to an embodiment of the present invention, and FIG. 5 is a bottom view of a sound absorbing panel according to an embodiment of the present invention.

As shown in FIGS. 1 to 5 , the sound absorbing panel according to an embodiment of the present invention may be formed in a substantially polygonal polyhedron. For example, a polygonal polyhedron may be formed in the shape of a rectangular parallelepiped. At this time, the bottom of the sound-absorbing panel is open, and the inside is empty. The sound absorbing panel may have a front part 10, a side part 20 and a rear part 30 formed therein.

The front portion 10 is formed in a polygonal shape, has a predetermined size and thickness, and is configured to reduce noise by absorbing sound generated in a space in which a sound absorbing panel is installed. This front portion 10 is the outer surface of the sound absorbing panel and refers to the upper surface of the rectangular parallelepiped shape. The front part 10 may be manufactured based on a polyester material, and the side part 20 may be formed by bending from each side of the manufactured front part 10 . At this time, the front part 10 may be formed to have a maximum width of 600 mm and a maximum length of 600 mm based on FIG. 2 .

Here, as shown in FIGS. 1 and 2 , the front portion 10 may have a surface area 100 and at least one curved area 110 formed in the surface area 100 .

The surface region 100 is made of compressed polyester obtained by compressing polyester, and the compressed polyester may serve as a plate vibration type sound absorbing material. Accordingly, the surface area 100 can effectively reduce noise in a low frequency band.

The polyester used at this time may be a mixture of recycled polyester and LM polyester (Low Melting Polyester).

In addition, a curved region 110 connected from one side to the other facing side may be formed on the front portion 10 . The bending area 110 is formed in a substantially waveform shape, and is formed in a concave groove shape up to the corner 200 portion of the front portion 10 .

At this time, the upper curve may be referred to as the first curve 111 and the lower portion may be referred to as the second curve 112 . A groove region 113 concavely formed in a groove shape may be formed in a region between the first curve 111 and the second curve 112 .

Specifically, as shown in FIG. 4, the groove area 113 refers to an area between the first curve 111 and the second curve 112, and the groove area 113 is the first curve 111 and the second curve 112. 2 The further away from the bend 112, the deeper it is and is formed concavely. That is, the depth is shallow near the first curve 111 and the second curve 112, and the depth is deep as the distance from the first curve 111 and the second curve 112 increases. Accordingly, the groove area 113 is formed to be the deepest in the central portion 1130 between the first curve 111 and the second curve 112 . Here, the groove area 113 may be formed to a thickness of 4 mm to 10 mm.

In addition, the central portion 1130 of the groove area 113 is formed to be thicker in the plane direction when viewed in cross section. Accordingly, the central portion 1130 may be formed to be 2 mm to 10 mm thicker than other portions of the groove area 113 . It may be preferably 2 mm to 4 mm thicker. Accordingly, unlike the surface area 100 , the groove area 113 can effectively reduce noise in the mid- and high-frequency band.

Here, two groove areas 113 may be formed in one bending area 110 according to implementation.

In addition, the first curve 111 and the second curve 112 may be vertically symmetrical, left-right symmetrical, or origin symmetrical.

In addition, the curved region 110 formed in a wave shape may be formed of crests and valleys. Accordingly, the waveform of the first curve 111 may consist of two peaks and one valley, and the waveform of the second curve 112 may consist of one peak and two valleys.

Like the front part 10, the side part 20 reduces noise by absorbing the sound generated in the space where the sound absorbing panel is installed, and at the same time, a separate bracket for installing the sound absorbing panel is coupled. As shown in FIG. 3, the side portion 20 is formed by bending, that is, bending at a predetermined angle at four sides of the front portion 10, and the corner 200 is formed with an inclination.

That is, the edge 200 of the side portion 20 is inclined to be wider than the front portion 10 as it extends from the surface of the front portion 10 to the bottom when viewed from the side. In other words, it is formed to be inclined so that the angle increases from the end of the front part 10 to the outside of the front part 10 . The side portion 20 has a substantially trapezoidal cross section. At this time, the length of the side portion 20 may be 55mm to 65mm.

The side portion 20 is made of compressed polyester obtained by compressing polyester in the same way as the surface area 100, and the compressed polyester may serve as a plate vibration type sound absorbing material. Accordingly, the side part 20 together with the surface area 100 can effectively reduce noise in a low frequency band.

If, when the sound absorbing panel according to the present invention is installed on the wall, the front part 10 and the side part 20 may surround the wall to form a back air layer inside the sound absorbing panel. Accordingly, by using the plate vibration type sound absorbing material and the back air layer, noise in a low frequency band may be reduced and sound absorbing performance may be enhanced.

The rear part 30 is the opposite surface of the front part 10 and refers to the inner surface of the sound absorbing panel. Since the curved region 110 is concavely formed in the front part 10, the curved region 110 may be convexly formed on the rear part 30.

Meanwhile, in the present invention, a plurality of rear protrusions 300 may be formed on the rear portion 30 according to the practice. The rear projection 300 reinforces the rigidity of the sound absorbing panel and serves to support the gap between the front portion 10 and the side portion 20, and protrudes from the rear portion 30 to a predetermined area, and the side portion 20 ) It may be formed by continuing to the back side of the back side and the front side (10).

At this time, as shown in FIG. 5, the rear protrusions 300 may be formed in three on each side between the two curved regions 110, and 7 on each of the upper and lower portions of the rear portion 30. can be formed individually. Accordingly, the rear projection 300 may additionally reduce noise through the convexly protruding area, which may also contribute to improving sound absorption performance.

Meanwhile, illustratively in the present invention, the low frequency band includes a range of about 125 Hz to 250 Hz, the middle frequency band includes a range of about 500 Hz to 1,000 Hz, and the high frequency band includes a range of about 2,000 Hz or more.

Hereinafter, it will be described that the sound absorbing panel according to the present invention absorbs sound in a broad band with reference to the drawings.

6 is a view schematically illustrating reducing noise in a middle and high frequency band through a curved region in a sound absorbing panel according to an embodiment of the present invention, and FIG. 7 is a view of a low frequency band in a sound absorbing panel according to an embodiment of the present invention It is a drawing for schematically explaining noise reduction.

Sound absorbing panels according to embodiments of the present invention may be installed on walls, ceilings, or floors of buildings, ships, vehicles, and railroads. At this time, the sound absorbing panel may be installed with the bending area 110 facing horizontally or vertically facing the sound absorbing panel, some of the sound absorbing panels facing horizontally, and some of the sound absorbing panels facing vertically. may be installed.

In addition, although the present invention shows that two bending areas 110 are formed on the front part 10 as an example, according to the implementation, a minimum of one to a maximum of four bending areas 110 may be formed.

When noise is generated, it can be reduced by effectively absorbing the sound in different regions of the middle frequency band and the low frequency band.

First, as shown in FIG. 6 , noise in the mid- and high-frequency band may be absorbed and reduced through the curved region 110 formed on the front portion 10 . That is, the upper boundary of the curved region 110 is formed by the first curved line 111 and the lower boundary is formed by the second curved line 112 and has a predetermined boundary around the first curved line 111 and the second curved line 112. It can be formed in the size of. The curved region 110 is formed in a concave groove shape toward the central portion 1130 between the first curved portion 111 and the second curved portion 112 . Accordingly, the bending area 110 is thickly formed on the front portion 10 so that noise in the mid- and high-frequency band can be absorbed.

Specifically, the bending area 110 is formed in the form of a concave groove, which may have a thickness of 4 mm to 10 mm. In addition, the central portion 1130 in the curved region 110 is formed to be thicker than the first curved portion 111 and the second curved portion 112 near the starting points. As described in FIG. 4 , the central portion 1130 may be formed to have a thickness of 2 mm to 10 mm. In addition, the front part 10 may be formed to have a maximum width of 600 mm and a maximum length of 600 mm. Accordingly, the length of the bending region 110 also increases.

Therefore, the bending area 110 and the central portion 1130 of the bending area 110 thicken the front part 10, and since the front part 10 is formed with a maximum width of 600 mm and a maximum length of 600 mm, the space is wide. It is possible to increase the sound absorption rate not only in the high frequency band but also in the mid-frequency band over the region.

Here, the sound absorption coefficient is related to the thickness as well as the material of the sound absorbing material. That is, as the thickness of the sound absorbing material increases, sound in the middle and low frequency band is more easily absorbed. Therefore, it is possible to easily absorb sound by expanding not only the high frequency band but also the noise in the middle and low frequency band. Accordingly, in the present invention, a portion of the front portion 10 is made in a curved shape to increase the thickness, and the central portion 1130 in the curved area 110 is particularly thick, thereby effectively absorbing noise in the middle and low frequency band. can be reduced by doing so.

In addition, as shown in FIG. 7 , the surface area 100 and the side portion 20 can effectively absorb and reduce noise in a low frequency band.

The surface area 100 and the side portion 20 are also made of a polyester material, and at this time, the surface area 100 and the side portion 20 are made of compressed polyester obtained by compressing polyester. Here, the compressed polyester may serve as a plate vibration type sound absorbing material.

When an air layer is placed behind a plate-like material such as plywood or gypsum board, sound energy is converted into kinetic energy by the resonant vibration of the plate and sound is absorbed. This rear air layer is formed as an effective sound absorption structure in a low frequency band. This plate vibration is caused by not only the role of the plate as a mass, but also the role of the rear air layer as a spring and stiffness, etc. acting in a complex way.

Here, in the present invention, since the length of the side portion 20 is formed to be 50 mm to 60 mm, when installed on a wall surface, the surface area 100 and the side portion 20 surround the wall surface to form a back air layer into the sound absorbing panel. there is.

Therefore, the surface area 100 serves as a plate-shaped sound absorbing material so that sound energy is converted into kinetic energy by the resonant vibration of the surface area 100 to the back air layer formed by the surface area 100 and the side surface portion 20 surrounding the wall surface. It can effectively absorb and reduce noise in the low frequency band.

At this time, the maximum sound absorption frequency of the plate-type sound absorbing material, that is, the resonance frequency, varies depending on the size, weight, stiffness, thickness of the rear air layer, and the like of the plate. In the present invention, since the front part 10 is formed to have a maximum width of 600 mm and a maximum length of 600 mm, and the length of the side part 20 is formed to 50 mm to 60 mm, the rear air layer can be secured in a large volume, which is the rear air layer. to make it thicker. Therefore, the sound absorbing panel of the present invention can effectively reduce noise in a low frequency band.

As a result, due to the polyester material, noise in the mid- to high-frequency band is generally absorbed, and due to the structural characteristics of the bending area 110, not only the mid- to high-frequency band but also the noise in the mid-to-low frequency band can be effectively absorbed and reduced.

In addition, the surface area 100 and the side portion 20 not only basically absorb noise in the middle and high frequency band, but also the plate vibration absorption material formed of the surface area 10 and the side portion 20 when the sound absorbing panel is installed on the wall, and Due to the back air layer, noise in the low frequency band can be absorbed and effectively reduced.

Therefore, the sound absorbing panel can effectively reduce the noise in a broadband by absorbing the noise in the middle frequency band and the noise in the low frequency band.

Hereinafter, a process of adding a layer to the front part 10 will be described with reference to drawings.

8 is a view schematically showing that a layer is additionally attached to the front part 10 in a side view of a sound absorbing panel according to an embodiment of the present invention.

As shown in FIG. 8 , an additional layer may be attached to the front portion 10 of the sound absorbing panel according to an embodiment of the present invention during the manufacturing process. Such an additional layer 400 may be provided as a layer made of polyester material in the same manner as the front portion 10, and may have a mass of 200 g/m ³ to 300 g/m ³ .

The additional layer 400 may be added to the front part 10 by pressing it with a press while it is attached to the front part 10 during the manufacturing process.

At this time, the color of the additional layer 400 may be provided with a color different from that of the front part 10 . That is, in the present invention, by providing a different color from the color of the sound absorbing panel basically provided by the additional layer 400, it is possible to provide aesthetic beauty. Therefore, the sound absorbing panel of the present invention can be conveniently installed by a user selecting sound absorbing panels manufactured in various colors according to his/her taste.

In addition, as the additional layer 400 is added, the sound absorption performance of the front part 10 may be enhanced.

Hereinafter, it will be described how to additionally reduce noise when a plurality of sound absorbing panels according to the present invention are installed with reference to the drawings.

9 is a view schematically illustrating the assembly and installation of a plurality of sound absorbing panels according to an embodiment of the present invention.

As shown in FIG. 9 , sound absorbing performance may be further enhanced when a plurality of sound absorbing panels according to an embodiment of the present invention are arranged and installed in succession.

Specifically, a user may install a sound absorbing panel by arranging the plurality of front parts 10 adjacent to an inner wall of a building. For example, it may be installed on the inner wall of a building by combining a separate bracket (not shown) and four side parts 20, respectively. Accordingly, a plurality of sound absorbing panels may be finally installed.

Here, when a plurality of sound absorbing panels are installed, sound absorption performance may be enhanced through a gap between the side parts 20 and the side parts 20 due to the inclined side part 20 . That is, the side portion 20 formed by bending from the front portion 10 extends while being inclined at an angle greater than 90 degrees as it descends, as shown in FIG. 9 . Accordingly, when the plurality of sound absorbing panels are installed, if the side parts 20 are in close contact with each other, a V-shaped space may be formed between the side parts 20 and the side parts 20 .

As a result, when noise is transmitted in a state where a plurality of sound absorbing panels are installed, not only the sound is absorbed and reduced in the surface area 100 and the curved area 110 of the front portion 10, but also the side portion 20 and the side portion ( 20), additional sound absorption occurs even in the space between them, so that the sound absorption performance can be enhanced.

In addition, it has been described that the bending area 110 is formed from one facing side to the other side. This is so that when the noise transmitted to the bending area 110 is not absorbed yet, it is guided to both sides of the bending area 110 so that the sound can be absorbed into the V-shaped space of the side part 20. Accordingly, it is possible to absorb sound not only in the front part 10 but also in the side part 20, so that the sound absorption performance can be enhanced.

Meanwhile, in the present invention, the sound absorbing panel according to the present invention may be manufactured through the following manufacturing method.

First, a first mixed material obtained by mixing recycled polyester and LM polyester (Low Melting Polyester) in a weight ratio of 20 to 60%: 80 to 40% may be created.

Thereafter, a second mixed material obtained by mixing recycled polyester and LM polyester at a weight ratio of 80 to 40%: 20 to 60% may be created.

Next, the first mixed material and the second mixed material may be mixed and heated.

Finally, a sound absorbing panel may be manufactured by performing compression molding to form the front portion 10 and the bent side portion 20 in a predetermined thickness and shape.

In this case, the polyester may have a weight of 1,500 g/m ³ to 2,000 g/m ³ . Accordingly, the sound absorbing panel is light and can be easily installed because only one front part 10 is installed on a wall of a building without the need for separate assembly.

In addition, the front part 10 can be heated using an oven when heating. At this time, the oven temperature is 300 ° C to 350 ° C, the heating time of the oven is 70 seconds to 200 seconds, and then pressurized using a press. At this time, the pressing time may be made between 30 seconds and 200 seconds.

The preferred embodiment of the present invention described above has been disclosed for illustrative purposes, and various modifications, changes and additions will be possible to those skilled in the art with ordinary knowledge of the present invention within the spirit and scope of the present invention, and such modifications and changes and additions should be considered to fall within the scope of the claims of the present invention.

10: front part
100: surface area
110: bending area
111: first bend
112: second bend
113: home area
1130: central part
20: side part
200: corner
30: rear part
300: back projection
40: Additional Layers

Claims (14)

In the method for manufacturing a sound-absorbing panel,
Creating a first mixed material by mixing recycled polyester and LM polyester (Low Melting Polyester) at a weight ratio of 20 to 60%: 80 to 40%;
Creating a second mixed material by mixing recycled polyester and LM polyester at a weight ratio of 80 to 40%: 20 to 60%;
mixing and heating the first mixed material and the second mixed material; and
Performing compression molding to form a front portion with a predetermined thickness and shape to manufacture a sound absorbing panel,
The front portion is formed with a surface area and at least one curved area, a portion of which is formed in a groove shape in the surface area,
The bending area is
Including a first curve that is the boundary of the upper portion, a second curve that is the boundary of the lower portion, and a groove area between the first curve and the second curve,
The groove region is formed to be thicker than the vicinity of the first curve and the second curve in the central portion,
method.
According to claim 1,
The front part is formed with a maximum width of 600 mm and a maximum length of 600 mm,
method.
According to claim 2,
A side portion bent from each side of the front portion is formed,
The length of the side portion is formed to 50 mm to 60 mm,
method.
According to claim 3,
the surface region and the side portions are made of compressed polyester;
The compressed polyester serves as a plate vibration type sound absorbing material,
method.
According to claim 4,
When the surface area and the side part are installed on the wall, they form a wall and a back air layer to absorb noise in the low frequency band.
method.
According to claim 1,
The step of mixing and heating the first mixed material and the second mixed material is heated in an oven at 300 to 350 ° C, and the heating time is 70 seconds to 200 seconds,
method.
According to claim 1,
The step of performing the compression molding to form a front portion to a predetermined thickness and shape to manufacture a sound absorbing panel is pressurized using a press, the pressing time is 50 seconds to 200 seconds,
method.
According to claim 1,
The produced sound-absorbing panel has a polyester weight of 1,500 g/m ³ to 2,000 g/m ³ ,
method.
In the sound absorbing panel,
It is formed in a polygonal shape and includes a front portion having a predetermined size and thickness,
The front portion is formed with a surface area and at least one curved area, a portion of which is formed in a groove shape in the surface area,
The bending area is
Including a first curve that is the boundary of the upper portion, a second curve that is the boundary of the lower portion, and a groove area between the first curve and the second curve,
The groove region is formed to be thicker than the vicinity of the first curve and the second curve in the central portion,
sound absorbing panel.
According to claim 9,
The groove region is formed in the form of a concave groove having a shallow depth near the first curve and the second curve and a deeper depth as it moves away from the first curve and the second curve.
sound absorbing panel.
According to claim 10,
The bending area is formed by connecting from one side of the front portion to the other facing side,
The first curve and the second curve are formed in the shape of a wave,
The first curve and the second curve formed in the shape of the wave are formed symmetrically with each other,
sound absorbing panel.
According to claim 11,
The concave groove shape is formed to a thickness of 4 mm to 10 mm,
sound absorbing panel.
delete According to claim 9,
A side portion bent from each side of the front portion is formed,
The side portion is formed inclined outward from the front portion when viewed in cross section,
sound absorbing panel.

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